Abstract: A method of detecting a possible collision in a medical procedure that involves a medical system, includes: obtaining an image of a patient that is supported on a patient support; determining a first model using a processing unit based at least in part on the image, at least a part of the first model representing a surface of the patient; determining a second model using the processing unit, the second model representing a first component of the medical system; virtually moving the first model, the second model, or both, using a collision prediction mechanism to simulate a movement of the first component of the medical system to determine whether there is a possible collision between the first component and the patient; and generating an output to indicate the possible collision or an absence of the possible collision.

Abstract: A method of detecting a possible collision in a medical procedure that involves a medical system, includes: obtaining an image of a patient that is supported on a patient support; determining a first model using a processing unit based at least in part on the image, at least a part of the first model representing a surface of the patient; determining a second model using the processing unit, the second model representing a first component of the medical system; virtually moving the first model, the second model, or both, using a collision prediction mechanism to simulate a movement of the first component of the medical system to determine whether there is a possible collision between the first component and the patient; and generating an output to indicate the possible collision or an absence of the possible collision.

Abstract: A facility for processing data is described. The facility receives a stream of digital location indications, each location indication identifying a location of a patient while undergoing radiation therapy. In response to each location indication of the string, in substantially real-time relative to the receipt of the position indication, the facility performs an action responsive to the location indication.

Abstract: A facility for processing data is described. The facility receives a stream of digital location indications, each location indication identifying a location of a patient while undergoing radiation therapy. In response to each location indication of the string, in substantially real-time relative to the receipt of the position indication, the facility performs an action responsive to the location indication.

Abstract: A facility for performing patient localization for radiation therapy is described. The facility activates two or more discrete software modules, and performs interactions between the activated software modules. Based upon the performed interactions, the facility performs patient localization for a radiation therapy session.

Abstract: A system automatically prepares and analyzes a macromolecule prepared from a complex liquid mixture. To prepare the macromolecule, a controller executing executable instructions, such as compiled software or firmware, operates a hydraulic subsystem in response to operational input, which may be interpreted by the executable instructions at run-time. To analyze the prepared macromolecule, an apparatus for capillary electrophoresis includes a liquid source, inlet chamber, capillary electrophoresis column, and controller that may operate under control of executable instructions and operational input in a similar manner. The system may require validation and approval by a regulatory body, such as the FDA. Based on the de-coupled configuration of the executable instructions and operational input, the system can be validated and approved with the executable instructions independent of the operational input, and vice-versa. A method for distributing the system based on this feature is also provided.

Abstract: A system automatically prepares and analyzes a macromolecule prepared from a complex liquid mixture. To prepare the macromolecule, a controller executing executable instructions, such as compiled software or firmware, operates a hydraulic subsystem in response to operational input, which may be interpreted by the executable instructions at run-time. To analyze the prepared macromolecule, an apparatus for capillary electrophoresis includes a liquid source, inlet chamber, capillary electrophoresis column, and controller that may operate under control of executable instructions and operational input in a similar manner. The system may require validation and approval by a regulatory body, such as the FDA. Based on the de-coupled configuration of the executable instructions and operational input, the system can be validated and approved with the executable instructions independent of the operational input, and vice-versa. A method for distributing the system based on this feature is also provided.

Abstract: The invention provides human cyclic nucleotide phosphodiesterases (HSPDE10A), polynucleotides that encode HSPDE10A, and antibodies that specifically bind HSPDE10A. The invention also provides expression vectors, host cells, agonists, and antagonists and methods for diagnosing or treating disorders associated with expression of HSPDE10A.

Abstract: The invention provides human cyclic nucleotide phosphodiesterases (HSPDE10A) and polynucleotides which identify and encode HSPDE10A. The invention also provides expression vectors, host cells, antibodies, agonists, and antagonists and methods for diagnosing or treating disorders associated with expression of HSPDE10A.

Abstract: The invention provides human cyclic nucleotide phosphodiesterases (HSPDE10A) and polynucleotides which identify and encode HSPDE10A. The invention also provides expression vectors, host cells, antibodies, agonists, and antagonists. The invention also provides methods for diagnosing, treating, or preventing disorders associated with expression of HSPDE10A.